DE3408187A1 - IMAGE PROCESSING DEVICE - Google Patents

Description

The invention relates to an image processing apparatus for processing image signals and, more particularly, to a Image processing device for reproducing an image of high quality.

To explain the state of the art from which the invention is based, reference is made to the accompanying drawings, namely FIGS. 1 to 3, referred to. Show it:

Fig. 1 is a schematic illustration of a conventional laser beam printer;

Fig. 2 is a circuit diagram of a conventional pulse width modulation circuit for pulse width modulation of a 2-bit digital signal;

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Fig. 3A is a flow chart showing the waveform of the clocks on the respective elements of the circuit of Fig. 2;

FIG. 3B is an illustration of the pulse widths obtained by the pulse width modulation circuit of FIG Laser beam modulation signals or the positions and sizes of those shown in FIG Circuit recorded points.

In a conventional laser beam printer, a laser beam is generated in accordance with a digital image signal modulated, and a photosensitive body becomes with the Laser beam scanned by a rotating polygon mirror to produce a digital image. Fig. 1 shows a Example of such a known type of laser beam printer. A semiconductor laser 1 generates a laser beam which is deflected from the rotating polygon mirror 2 to a photosensitive roller 3. In accordance with one digital image signal, the laser 1 modulates the laser beam which is directed to the rotating polygon mirror rotating in the direction of the arrow A. 2 falls, with which the photosensitive body 3 is scanned, which rotates in the direction of arrow 3 and on which a latent digital image is formed.

In a conventional laser beam printer of this type, the laser beam is modulated according to binary signals "1" and "O" in order to to create an image. Since the rise characteristic of the laser beam is steep, it is difficult to determine the performance of the To modulate the laser beam to create an image with a color shade (tonality) based on the emission characteristics to reproduce. The dither method is as one method for reproducing an image with tint (a calf tone image) of binary signals known. According to the dither or dither method is made in accordance with the area ratio

A color tone (a gray level) is reproduced within each small image area from black picture elements to white picture elements. Therefore, if the number of thresholds or heights of the dither matrix is reduced, the resolution worsened. There has been a method of providing color tone in an output image by pulse modulation proposed a laser beam. FIGS. 2 and 3 show an exemplary embodiment for a device for carrying out this method, FIG. 2 being an example of a. Pulse width modulation circuit for Performing pulse width modulation of a 2-bit digital four-value (four-level) image signal. A laser diode la generates a laser beam. Digital 2-bit image signals (DATA O and DATA 1) received. A transmission (transfer) clock CLK for the transmission of the digital 2-bit signals (DATA O and DATA 1) is applied to a transfer clock input terminal 4. A clock CLKH with three times the frequency of the clock CLK is connected to a clock input terminal 5. A decoder 6 dec. Encodes the digital 2-bit signals a 4-bit digital signal.

A pulse width modulation circuit (PDM) 7 generates clocks CLKH1, CLKH2 and CLKH3 of different pulse widths from the clock CLKH, which has three times the frequency of the clock CLK. A latch 8 soeichert d _as decoded 4-bit digital signal at the clocking of the transfer clock CLK, and is connected to an OR gate 10 via an input terminal of respective AND circuits. 9 A transistor 11 is inserted between the output terminal of the OR gate 10 and the laser diode la to drive it.

The digital 2-bit signals (DATA O and DATA. 1) received at the inputs 2a and 3a are converted into decrypted 4-bit signals by the decoder 6 when the transfer clock CLK is clocked. In the meantime, the clock CLKH, which has three times the frequency of the transfer clock CLK, is converted by the pulse width ^{modulation circuit 7 into the three} three clocks CLKH1, CLKH2 and CLKH3, which have different duty cycles. 3A shows the waveforms of the respective clocks. The waveform (1) of the transfer clock CLK has a period T and a duty cycle of 50%. The waveform (2) of the clock CLKH has a period T / 3, a duty cycle of 50% and is synchronous with the transfer clock CLK. The pulse width modulation circuit 7 modulates the clock CLKH with the period T / 3 and the clocks CLKHl, CLKH2 and CLKH3, which the period T, the duty cycle of 1/3 or 2/3 or 1 and the waveforms (3) to ( 5) have. The clocks CLKH1, CLKH2 and CLKH3 correspond to (0,1), (I ^ O) and (1, 1) of the 2-bit digital signals (DATA 0 and DATA 1), respectively. These waveforms with the different duty ratios and the 4-bit signal stored and decoded in the memory are gated or faded in by the AND circuits 9 so that they have pulse widths corresponding to the digital 2-bit image signals. The pulse-modulated, decoded upper 3-bit signal is converted into a 1-bit signal by the OR element 10. The signal from the OR gate 10 drives the laser diode la via the transistor 11. Therefore, the pulse widths of the modulation signal of the laser beam which correspond to the 2-bit digital image signals (DATA 0 and DATA 1), that is, the turn-on timing and the turn-on time, are shown in FIG. 3B. As a result, be in accordance with

the 2-bit digital signals (O, O), (O, 1), (1, O) and (1, 1) generates pulse width modulated laser beams "0", "1", "2" and "3" shown in Fig. 3B, respectively. Fig. 3B also shows the location and size of the dots recorded on the photosensitive body, where the dashed part is actually recorded Part corresponds to. "0" in Fig. 3B is a picture element with no recorded content, and "3" is the maximum dot size for a picture element.

In a pulse width modulation method of the above kind the centers of the pulse widths of the respective digital signals (0, 0), (0, 1), (1, 0) and (1, 1) and differ thus the centers for the picture elements - from one another. Consequently, the dots of the halftone image part (raster image part) no grid shape (a regular matrix), resulting in moderate gradation, generation of interference fringes etc. leads.

The object of the invention is to eliminate the problems mentioned above.

It is thus an object of the invention to provide an image processing device capable of producing an image output of high quality and sharpness.

Another object of the invention is to provide an image processing apparatus which is simple in structure but has the ability to control the positions of the recording dots of different sizes.

Further, it is intended to provide an image processing apparatus capable of producing a color image output of high quality. .

The object, the objectives and the advantages of the subject matter of the invention can be found in the following, on the drawings Referring description clearly. Show it:

4 shows a circuit diagram for a pulse width modulation in an embodiment according to the invention;

FIG. 5A is a flow chart showing the clocks at the relevant Represents elements of the circuit of Fig. 4;

FIG. 5B is an illustration of the pulse widths obtained by the pulse width modulation circuit of FIG Laser beam modulation signals or the positions and sizes of the circuit shown in FIG recorded points.

The invention is based on the preferred embodiment described, wherein in the circuit diagram of the image processing apparatus of Fig. 4 parts, the elements or parts of Fig. 2 are the same, are identified by the same reference numerals and will not be explained again.

Latches 12 and 13 store clock pulses CLKHl and CLKH2 synchronously with a clock CLKH, which has Signal lines 14, 15 are fed to the buffers 12 and 13, respectively. An inverter

16 generates a phase shifted by 180 ° from the clock CLKH Clock CLKL. Fig. 5A shows the waveforms of the clocks indicated in Fig. 4, where the waveforms (1), (2), (3), (4) and (5) in Fig. 5A are the same as those of Fig. 3A. A transfer clock CLK has the waveform (I "). The clock CLKH with three times the frequency of the transfer clock CLK has the waveform (2). A clock CLKHl has the waveform (3), a clock CLKH2 has the waveform (4), and a clock CLKH3 has the waveform (5). In the circuit diagram of Fig. 4, the clock CLKHl by a period of

Clock CLKH is delayed by the latch 12 to generate a clock CLKHl ¹ with the waveform (3 ¹ ), which has a period delayed by 1 / 3T from the clock CLKH and a duty cycle of 1/3. The signal CLKHl 'is applied to an AND circuit 9 via line 17. The clock CLKH2 is delayed by half the period of the clock CLKH by the latch 13 to generate a pulse CLKH2 'of waveform (4') having a period delayed by T / 6 from the clock CLKH and a duty cycle of 2/3 Has. The signal CLKK2 ¹ is fed to a further AND circuit 9 via a signal line 18. Accordingly, the gate signals of the AND circuits 9 corresponding to the 2-bit digital signals (0, 1), (1, 0) and (1, 1) have waveforms (3 '), (4 ¹ ) and (5) ) mil ·, the duty cycles shown in FIG.

This is why the pulse widths of the laser beam modulation signals arise corresponding to the 2-bit digital signals (0, 0), (0, 1), (1, 0) and (1, 1), i.e. the switch-on timing and the on-time of the laser beam shown in Fig. 5B.

In this way, the laser beams become "0", "1", "2" and "3" which are pulse width modulated as shown in Fig. 5B in accordance with the 2-bit digital signals (0, 0), (0, 1), (1, 0) and (1, 1) are generated. As in the case of Fig. 3B, Fig. 5B shows the locations and sizes of the recordings Writing points on the photosensitive roller, where the hatched parts in Fig. 5B represent the actual points represent and "0" a picture element without recording content, "3" represent a maximum size for a picture element.

As can be seen from Fig. 5B, since the centers of the points (central positions of the points for Hilde learners) can be made to align independently of digital values, the image points can be designed in a matrix form will. Accordingly, the present invention provides an image processing apparatus capable of reproducing a halftone image of good quality.

In the above embodiment, the center of each point of each size is on the central position of the picture element aligned. A similar effect can, however, also be achieved if the clock is generated is controlled for each case so that the point of each size is constantly a center of one picture element (maximum Recording point). In the above embodiment, a 2-bit digital signal is pulse width modulated, However, the centers of the points can also be aligned with the central positions of the image elements, when a digital signal of 3 bits or more is pulse width modulated. Furthermore, the subject matter of the invention is although the description has been based on a laser beam, the same applies to other types of image processing apparatus applicable, for example in recording devices such as inkjet printers, thermal printers or the like, wherein an image is reproduced with a collective point body 'and the point size is changeable.

Furthermore, the invention is also applicable to a color ink jet printer applicable; with such a printer, if a red dot is printed on a yellow one, the The size of the red dot changed in different ways, using different gradations or shades of color be generated. When the center of a red dot of different sizes at the center of a yellow

Point is superimposed, so an image of good color balance (balance) can be reproduced.

The invention is also not limited to the circuit described above and can be applied to circuits of the same type. in which the positions of the points of different sizes can be controlled, can be applied as well not limited to the described, special execution Ji oini is because changes and modifications can be made within the scope of the invention.

According to the invention, an image processing device has a Decoder for decoding input image data, a pulse width modulation formwork for generating a Signal for pulse width modulation of a laser beam from a laser diode in accordance with the dec Image data and buffer for delaying the output signal of the pulse width modulation circuit on. The device produces a halftone image, with the center of each point being of a different size coincides with that of a picture element.

Overall, with a device according to the invention, an output image of high quality and excellent gradation can be achieved can be obtained.

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Claims (10)

Claims - By a device (6) for inputting image data and - by means (7) for forming a signal which corresponds to a size of a recording point changes with the image data entered by the input device, wherein the signal forming means forms the signal so that a center of the recording point coincides with a given position. 2. Apparatus according to claim 1, characterized in that the means forming the signal comprises pulse width modulation means (7) which determine the pulse width of a pulse signal in accordance with modulates the input data entered by the input device (6). 3. Apparatus according to claim 1 or 2, characterized in that the device forming the signal (7) is a clock switching device (12, 13) indicating a generation period of the pulse width modulated signal in accordance with switches with the image data entered by the input device (6). 4. Apparatus according to any one of claims 1 to 3, characterized by a beam in accordance with the Pulse signal generating device (11). 5. Apparatus according to any one of claims 1 to 4, characterized in that the input device is a Decoding means (6) comprising the image data of a plurality of input means through the input means Bits decoded. 6. Image processing device, marked - By a device (6) for inputting image data and - By means (7) for 3 forming a signal, the size of a recording point in accordance with - changes the image data entered by the input device, wherein the signal forming means forms the signal so that each of all of the recording points of different size includes at least a center of a maximum recording point. 7. Apparatus according to claim 6, characterized in that the device forming the signal is a pulse width modulation device (7), which includes the impulse width of a pulse signal in accordance with that input from the input device (6) Modulated image data. 8. Apparatus according to claim 6 or 7, characterized in that the device forming the signal (7) is a clock switching device (12, 13) indicating a generation period of the pulse-modulated signal in accordance with switches with the image data entered by the input device (6). 9. Apparatus according to any one of claims 6 to 8, characterized by a beam in accordance with the Pulse signal generating device (11). 10. Apparatus according to any one of claims 6 to 9, characterized in that the input device has a Decoding means (6) comprising the image data of a plurality of inputted through the input means Bits decoded.